**Chapter 6**

*Earth Crust*

[38] Otsuki K, Dilov T. Evolution of hierarchical self-similar geometry of experimental fault zones: Implications for seismic nucleation and earthquake

Materials. 2014;**592-593**:121-124. DOI: 10.4028/www.scientific.net/

[46] Tarasov BG, Sadovskii VM, Sadovskaya OB. Analizis of fan waves in a laboratory model simulating the propagation of shear ruptures in rocks. Computational Mechanics of Solids. 2016;**9**(1):38-51. DOI: 10.7242/1999-6691/2016.9.1.4

KEM.592-593.121

size. Journal of Geophysical Research. 2005;**110**. DOI: B03303,

[39] http://www.geologyin.

christchurch-new-zealand/

from: http://www.temblor.net

Poland. 2013. pp. 165-170

[43] Tarasov BG, Guzev MA,

shear ruptures with friction

[44] Tarasov BG, Guzev MA. New insight into the nature of size dependence and the lower limit of rock strength. In: Malovichko AD, editor. Proceedings 8th International Symposium on Rockbursts and Seismicity in Mines. Russia: St-Petersburg; 2013. pp. 31-40

[45] Tarasov BG, Guzev MA.

Mathematical model of fan-head shear rupture mechanism. Key Engineering

s10704-017-0223-1

Sadovskii VM, Cassidy MJ. Modelling the mechanical structure of extreme

approaching zero generated in brittle materials. International Journal of Fracture. 2017. DOI: 10.1007/

[40] Chris R. Tectonics of the M7 earthquake near Christchurch. New Zealand; 2010. Available from: http://all-geo.org/ highlyallochthonous/2010/09/

com/2018/06/slow-earthquakes-on-san-

tectonics-of-the-m7-earthquake-near-

[41] Temblor. Temblor. 2017. Available

[42] Tarasov BG. Depth distribution of lithospheric strength determined by the self-unbalancing shear rupture mechanism. In: Proceedings of the International Symposium, Rock Mechanics for Resources, Energy and Environment (Eurock), Wroclaw,

10.1029/204JB003359

andreas-fault.html

**84**
